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Regularizer base class.
Used in the notebooks
Used in the tutorials |
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Regularizers allow you to apply penalties on layer parameters or layer activity during optimization. These penalties are summed into the loss function that the network optimizes.
Regularization penalties are applied on a per-layer basis. The exact API
will depend on the layer, but many layers (e.g. Dense
, Conv1D
, Conv2D
and Conv3D
) have a unified API.
These layers expose 3 keyword arguments:
kernel_regularizer
: Regularizer to apply a penalty on the layer's kernelbias_regularizer
: Regularizer to apply a penalty on the layer's biasactivity_regularizer
: Regularizer to apply a penalty on the layer's output
All layers (including custom layers) expose activity_regularizer
as a
settable property, whether or not it is in the constructor arguments.
The value returned by the activity_regularizer
is divided by the input
batch size so that the relative weighting between the weight regularizers
and the activity regularizers does not change with the batch size.
You can access a layer's regularization penalties by calling layer.losses
after calling the layer on inputs.
Example
layer = Dense(
5, input_dim=5,
kernel_initializer='ones',
kernel_regularizer=L1(0.01),
activity_regularizer=L2(0.01))
tensor = ops.ones(shape=(5, 5)) * 2.0
out = layer(tensor)
# The kernel regularization term is 0.25
# The activity regularization term (after dividing by the batch size)
# is 5
ops.sum(layer.losses)
5.25
Available penalties
L1(0.3) # L1 Regularization Penalty
L2(0.1) # L2 Regularization Penalty
L1L2(l1=0.01, l2=0.01) # L1 + L2 penalties
Directly calling a regularizer
Compute a regularization loss on a tensor by directly calling a regularizer as if it is a one-argument function.
E.g.
regularizer = L2(2.)
tensor = ops.ones(shape=(5, 5))
regularizer(tensor)
50.0
Developing new regularizers
Any function that takes in a weight matrix and returns a scalar tensor can be used as a regularizer, e.g.:
def l1_reg(weight_matrix):
return 0.01 * ops.sum(ops.absolute(weight_matrix))
layer = Dense(5, input_dim=5,
kernel_initializer='ones', kernel_regularizer=l1_reg)
tensor = ops.ones(shape=(5, 5))
out = layer(tensor)
layer.losses
0.25
Alternatively, you can write your custom regularizers in an object-oriented way by extending this regularizer base class, e.g.:
class L2Regularizer(Regularizer):
def __init__(self, l2=0.):
self.l2 = l2
def __call__(self, x):
return self.l2 * ops.sum(ops.square(x))
def get_config(self):
return {'l2': float(self.l2)}
layer = Dense(
5, input_dim=5, kernel_initializer='ones',
kernel_regularizer=L2Regularizer(l2=0.5))
tensor = ops.ones(shape=(5, 5))
out = layer(tensor)
layer.losses
12.5
A note on serialization and deserialization:
Registering the regularizers as serializable is optional if you are just training and executing models, exporting to and from SavedModels, or saving and loading weight checkpoints.
Registration is required for saving and loading models to HDF5 format, Keras model cloning, some visualization utilities, and exporting models to and from JSON. If using this functionality, you must make sure any python process running your model has also defined and registered your custom regularizer.
Methods
from_config
@classmethod
from_config( config )
Creates a regularizer from its config.
This method is the reverse of get_config
,
capable of instantiating the same regularizer from the config
dictionary.
This method is used by Keras model_to_estimator
, saving and
loading models to HDF5 formats, Keras model cloning, some visualization
utilities, and exporting models to and from JSON.
Args | |
---|---|
config
|
A Python dictionary, typically the output of get_config. |
Returns | |
---|---|
A regularizer instance. |
get_config
get_config()
Returns the config of the regularizer.
An regularizer config is a Python dictionary (serializable) containing all configuration parameters of the regularizer. The same regularizer can be reinstantiated later (without any saved state) from this configuration.
This method is optional if you are just training and executing models, exporting to and from SavedModels, or using weight checkpoints.
This method is required for Keras model_to_estimator
, saving and
loading models to HDF5 formats, Keras model cloning, some visualization
utilities, and exporting models to and from JSON.
Returns | |
---|---|
Python dictionary. |
__call__
__call__(
x
)
Compute a regularization penalty from an input tensor.